In-situ part position measurement

ABSTRACT

A probe for an additive manufacturing system includes a probe body having a first air port therethrough between an inlet and an outlet, and a location sensing probe extending from the probe body. The location sensing probe includes a probe end and a probe bar, the probe bar coupled between the probe body and the probe end, and a channel surrounding the probe bar, the channel having an inner tube having an inlet proximate the probe body and an outlet proximate the probe end. A method of determining a position of an item being printed in an additive manufacturing system, includes probing the position with a location sensing probe having a resolution finer than a print resolution of the print head.

CROSS-REFERENCE TO RELATED APPLICATION(S)

The present application claims the benefit of U.S. Provisional Patent Application Ser. No. 62/248,994 entitled “PROBE AND PRINTING METHODS FOR ADDITIVE MANUFACTURING SYSTEM” filed on Oct. 30, 2015, the contents of which are incorporated herein by reference in its entirety. Reference is also hereby made to co-filed U.S. Patent Application Ser. No. 62/249,972, entitled “PRINT FOUNDATION POSITIONING AND PRINTING METHODS FOR ADDITIVE MANUFACTURING SYSTEM”, and U.S. Patent Application Ser. No. 62/248,990, entitled “STARTER PIECE AND PRINTING METHODS FOR ADDITIVE MANUFACTURING SYSTEM”. Each of the patent applications and patents discussed herein is hereby incorporated by reference in its entirety.

BACKGROUND

The present disclosure relates to additive manufacturing systems for building three-dimensional (3D) items with layer-based, additive manufacturing techniques. In particular, the present disclosure relates to additive manufacturing systems for printing large or elongated 3D items, and methods for printing 3D items in the additive manufacturing systems.

Additive manufacturing systems are used to print or otherwise build 3D items from digital representations of the 3D items (e.g., AMF and STL format files) using one or more additive manufacturing techniques. Examples of commercially available additive manufacturing techniques include extrusion-based techniques, jetting, selective laser sintering, powder/binder jetting, electron-beam melting, and stereolithographic processes. For each of these techniques, the digital representation of the 3D item is initially sliced into multiple horizontal layers. For each sliced layer, one or more tool paths are then generated, which provides instructions for the particular additive manufacturing system to print the given layer.

For example, in an extrusion-based additive manufacturing system, a 3D item may be printed from a digital representation of the 3D item in a layer-by-layer manner by extruding a flowable item material. The item material is extruded through an extrusion tip or nozzle carried by a print head of the system, and is deposited as a sequence of roads on a substrate in an x-y plane while the print head moves along the tool paths. The extruded item material fuses to previously deposited item material, and solidifies upon a drop in temperature. The position of the print head relative to the substrate is then incremented along a z-axis (perpendicular to the x-y plane), and the process is then repeated to form a 3D item resembling the digital representation.

In fabricating 3D items by depositing layers of an item material, supporting layers or structures are typically built underneath overhanging portions or in cavities of 3D items under construction, which are not supported by the item material itself. A support structure may be built utilizing the same deposition techniques by which the item material is deposited. The host computer generates additional geometry acting as a support structure for the overhanging or free-space segments of the 3D item being formed. Support material is then deposited from a second nozzle pursuant to the generated geometry during the printing process. The support material adheres to the item material during fabrication, and is removable from the completed 3D item when the printing process is complete.

SUMMARY

An aspect of the present disclosure is directed to a probe for an additive manufacturing system, including a probe body having a first air port therethrough between an inlet and an outlet, and a location sensing probe extending from the probe body. The location sensing probe includes a probe end, a probe bar coupled between the probe body and the probe end, and a channel surrounding the probe bar, the channel including an inner tube having an inlet proximate the probe body and an outlet proximate the probe end.

Another aspect of the present disclosure is directed to a method of building a three-dimensional item in an additive manufacturing system, including printing a support structure for the three-dimensional item in a layer by layer manner along the printing axis, and printing a layer of the three-dimensional item while supporting the three-dimensional item laterally relative to the printing plane with the support structure while printing the three-dimensional item. Building the part further includes printing a fiducial structure having a known substantially vertical and a known substantially horizontal component.

Another aspect of the present disclosure is directed to a method of determining a position of an item being printed in an additive manufacturing system, including probing the position with a location sensing probe having a resolution finer than a print resolution of the print head.

DEFINITIONS

Unless otherwise specified, the following terms as used herein have the meanings provided below:

The terms “about” and “substantially” are used herein with respect to measurable values and ranges due to expected variations known to those skilled in the art (e.g., limitations and variabilities in measurements).

The term “printing onto”, such as for “printing a 3D item onto a print foundation” includes direct and indirect printings onto the print foundation. A “direct printing” involves depositing a flowable material directly onto the print foundation to form a layer that adheres to the print foundation. In comparison, an “indirect printing” involves depositing a flowable material onto intermediate layers that are directly printed onto the receiving surface. As such, printing a 3D item onto a print foundation may include (i) a situation in which the 3D item is directly printed onto to the print foundation, (ii) a situation in which the 3D item is directly printed onto intermediate layer(s) (e.g., of a support structure), where the intermediate layer(s) are directly printed onto the print foundation, and (iii) a combination of situations (i) and (ii).

The term “providing”, such as for “providing a chamber” and the like, when recited in the claims, is not intended to require any particular delivery or receipt of the provided item. Rather, the term “providing” is merely used to recite items that will be referred to in subsequent elements of the claim(s), for purposes of clarity and ease of readability.

The term “item” includes, by way of example only and not by limitation, standalone printed structures or parts that are utilized in combination with other parts to form a desired structure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a portion of an additive manufacturing system according to an embodiment of the present disclosure.

FIG. 2 is a perspective view of a platen and gantry portion of the additive manufacturing system of FIG. 1.

FIG. 3 is a top view of FIG. 2.

FIG. 4 is a perspective view of a portion of an additive manufacturing system illustrating an item movement system according to an embodiment of the present disclosure.

FIG. 5 is a top view of the portion of the additive manufacturing system of FIG. 4.

FIG. 6 is a perspective view of a drive system for an additive manufacturing system according to another embodiment of the present disclosure.

FIG. 7 is a perspective view of a drive rail and platen according to an embodiment of the present disclosure.

FIG. 8 is a close-up perspective view of a portion of a platen and drive system according to an embodiment of the present disclosure.

FIG. 9 is a perspective view of a starter piece according to an embodiment of the present disclosure.

FIG. 10 is a top view of the starter piece of FIG. 9.

FIG. 11 is a rear elevation view of the starter piece of FIG. 9.

FIG. 12 is a perspective view of another starter piece according to an embodiment of the present disclosure.

FIG. 13 is a rear elevation view of the starter piece of FIG. 12.

FIG. 14 is a perspective view of starter pieces in place on an additive manufacturing system according to an embodiment of the present disclosure, with parts of the system removed to show detail thereof.

FIG. 15 is a perspective view of a portion of an additive manufacturing system according to an embodiment of the present disclosure, showing starter pieces, a platen, and a portion of a drive system.

FIG. 16 is a close-up perspective view of a portion of an additive manufacturing system according to an embodiment of the present disclosure, showing starter pieces, a platen, and a portion of a drive system.

FIG. 17 is a perspective view of a location sensing probe according to an embodiment of the present disclosure.

FIG. 18 is a perspective view of the location sensing probe of FIG. 17 with portions removed to show further detail thereof.

FIG. 19 is a perspective view of the location sensing probe of FIG. 17 with portions removed to show further detail thereof.

FIG. 20 is a rear perspective view of the location sensing probe view shown in FIG. 19.

FIG. 21 is a front perspective view of the probe view shown in FIG. 19.

FIG. 22 is a perspective view of a fiducial according to another embodiment of the present disclosure.

FIG. 23 is a close-up view of the fiducial of FIG. 22.

FIG. 24 is a flow chart of a method according to an embodiment of the present disclosure.

FIG. 25 is a perspective view of a purge system according to an embodiment of the present disclosure

FIG. 26 is a side elevation view of the purge system of FIG. 25 in a Z detection position.

FIG. 27 is a side elevation view of the purge system of FIG. 25 in an X Y detection position.

FIG. 28 is a close-up perspective view of a portion of the purge system.

FIG. 29 is a perspective view of a portion of an additive manufacturing system according to another embodiment of the present disclosure.

FIG. 30 is a perspective view of the additive manufacturing system of claim 29 with a print foundation removed.

FIG. 31 is a close-up perspective view of a portion of an additive manufacturing system with a limit switch assembly according to another embodiment of the present disclosure.

DETAILED DESCRIPTION

The present disclosure is directed to an additive manufacturing system having an extended printing volume for printing long or tall 3D items. The additive manufacturing system includes a drive system for indexing a print foundation along a gantry or other support as the item is being printed. The additive manufacturing system includes in one embodiment a heated chamber having a port that opens the chamber to ambient conditions outside of the chamber. The system also includes one or more print heads configured to print a 3D item in a layer-by-layer manner onto a print foundation (e.g., a platen or other component having a receiving surface, which may be a build sheet fixed on a vacuum platen) in the heated chamber. As the printed 3D item grows on the print foundation, the print foundation may be indexed or otherwise moved through the port by the drive system in a coarse indexing adjustment. The print head may also be indexed to the layers of the three-dimensional item in a fine indexing adjustment. The printed 3D item may continue to grow out of the port until a desired length or height is achieved. The use of the port expands the printable volume along a printing axis of the system, allowing long or tall 3D items, such as airfoils, manifolds, fuselages, and the like to be printed in a single printing operation. As such, the 3D items may be larger than the dimensions of the additive manufacturing system, for example items having a length greater than a length of the build chamber.

The present disclosure is further directed to a location sensing probe for use with an additive manufacturing system having an extended printing volume for printing long or tall 3D items, methods for printing and for operating the additive manufacturing system with the location sensing probe, and methods for printing and operating the additive manufacturing system with starter pieces and a drive system. The location sensing probe can operate in three dimensions.

As discussed further below, the additive manufacturing system may be configured to print 3D items in a horizontal direction, a vertical direction, or along other orientations (e.g., slopes relative to the horizontal and vertical directions). In each of these embodiments, the layers of a printed 3D item may be stabilized by one or more printed supports or “scaffolds”, which brace the 3D item laterally relative to the printing axis of the system to address forces parallel to the build plane. The supports in horizontal printing act as a printed support structure.

In printing horizontally in a layer-by-layer manner from a print head nozzle, the layers of a 3D item being printed grow horizontally along the z-axis. As such, the “printing axis” in FIGS. 1-12 is a horizontal z-axis axis, and each layer extends parallel to a vertical x-y build plane.

In this situation, the layers of 3D item are printed on layers of support structure that extend from the starter pieces as described herein, to support the item weight to the support rails also described herein, which are correspondingly disposed on a platen.

For a horizontal printing operation, such as shown in FIGS. 1-12, the printing z-axis is a horizontal axis, and each layer of the 3D item and its support structure extend along the vertical x-y build plane. In further alternative embodiments, the layers of 3D items, support structures, and scaffolds may be grown along any suitable axis.

Horizontal Printing

FIGS. 1-12 illustrate example additive manufacturing systems of the present disclosure having extended printing volumes for printing long 3D items horizontally, such as discussed above for a 3D item. FIGS. 1-5 illustrate system 100, which is a first exemplary manufacturing system for printing or otherwise building 3D items, support structures, and/or scaffolds horizontally using a layer-based, additive manufacturing technique. Suitable systems for system 100 include extrusion-based additive manufacturing systems developed by Stratasys, Inc., Eden Prairie, Minn. under the trademark “FDM”, which are oriented such that the printing z-axis is a horizontal axis. In horizontal printing, the print axis is parallel to the print plane, and movement is perpendicular to the print plane.

As shown in FIG. 1, system 100 may rest on a table or other suitable surface 102, and includes chamber 104, platen 106, platen gantry 108, print head 110, head gantry 112, tool changer 113, and consumable assemblies 114. Chamber 104 is in one embodiment enclosed by chamber walls, and initially contains platen 106 for printing 3D items, support structures, and/or scaffolds. Support structures and scaffolds are described in further detail in co-pending application Publication No. 2014/0052287.

In the shown embodiment, chamber 104 includes a heating mechanism, which may be any suitable mechanism configured to heat chamber 104, such as one or more heaters and air circulators to blow heated air throughout chamber 104. Heating mechanism may heat and maintain chamber 104, at least in the vicinity of print head 110, at one or more temperatures that are in a range between the solidification temperature and the creep relaxation temperature of the item material and/or the support material. This reduces the rate at which the item and support materials solidify after being extruded and deposited (e.g., to reduce distortions and curling), where the creep relaxation temperature of a material is proportional to its glass transition temperature. Examples of suitable techniques for determining the creep relaxation temperatures of the item and support materials are disclosed in Batchelder et al., U.S. Pat. No. 5,866,058.

Chamber walls may be any suitable barrier to reduce the loss of the heated air from the build environment within chamber 104, and may also thermally insulate chamber 104.

In some embodiments, system 100 may be configured to actively reduce heat loss through a port in the chamber 104, such as with an air curtain, thereby improving energy conservation. Furthermore, system 100 may also include one or more permeable barriers at the port, such as insulating curtain strips, a cloth or flexible lining, bristles, and the like, which restrict air flow out of the port, while allowing platen 106 to pass therethrough.

In the shown example, print head 110 is a dual-tip extrusion head configured to receive consumable filaments or other materials from consumable assemblies 114 for printing a 3D item, support structure, and scaffold onto a receiving surface of platen 106. Examples of suitable devices for print head 110 include those disclosed in Crump et al., U.S. Pat. No. 5,503,785; Swanson et al., U.S. Pat. No. 6,004,124; LaBossiere, et al., U.S. Pat. Nos. 7,384,255 and 7,604,470; Leavitt, U.S. Pat. No. 7,625,200; Batchelder et al., U.S. Pat. No. 7,896,209; and Comb et al., U.S. Pat. No. 8,153,182.

In additional embodiments, in which print head 110 is an interchangeable, single-nozzle print head, a plurality of additional print heads 110 may be stored, for example within tool changer 113 as shown in FIG. 1, and may be interchangeably used for different printing functions. In one embodiment, tool changer 113 holds up to three separate print heads. Examples of suitable devices for each print head 110, and the connections between print head 110 and head gantry 112 include those disclosed in Swanson et al., U.S. Patent Application Publication No. 2012/0164256.

Print head 110 is supported by head gantry 112, which is a gantry assembly configured to move print head 110 in (or substantially in) the x-y plane parallel to platen 106. While the additive manufacturing systems discussed herein are illustrated as printing in a Cartesian coordinate system, the systems may alternatively operate in a variety of different coordinate systems. For example, head gantry 112 may move print head 110 in a polar coordinate system, providing a cylindrical coordinate system for system 100.

Suitable devices for consumable assemblies 114 include those disclosed in Swanson et al., U.S. Pat. No. 6,923,634; Comb et al., U.S. Pat. No. 7,122,246; Taatjes et al, U.S. Pat. Nos. 7,938,351 and 7,938,356; Swanson, U.S. Patent Application Publication No. 2010/0283172; and Mannella et al., U.S. patent application Ser. Nos. 13/334,910 and 13/334,921.

Suitable materials and filaments for use with print head 110 include those disclosed and listed in Crump et al., U.S. Pat. No. 5,503,785; Lombardi et al., U.S. Pat. Nos. 6,070,107 and 6,228,923; Priedeman et al., U.S. Pat. No. 6,790,403; Comb et al., U.S. Pat. No. 7,122,246; Batchelder, U.S. Patent Application Publication Nos. 2009/0263582, 2011/0076496, 2011/0076495, 2011/0117268, 2011/0121476, and 2011/0233 1164; and Hopkins et al., U.S. Patent Application Publication No. 2010/0096072. Examples of suitable average diameters for the filaments range from about 1.02 millimeters (about 0.040 inches) to about 3.0 millimeters (about 0.120 inches). Further in some embodiments, pellets of material are used as consumable feed stock. In such embodiments, a viscosity pump using a pellet-fed screw extruder may be used. Particle materials are fed to or drawn by the viscosity pump from particle hoppers (e.g., consumable assemblies 114), and are heated and sheared to an extrudable state, and extruded from a nozzle of the viscosity pump, as described in greater detail in U.S. Patent Application Publication No. 2014/0048981 and U.S. Pat. No. 8,955,558.

System 100 also includes in one embodiment controller 116, which is one or more control circuits configured to monitor and operate the components of system 100. For example, one or more of the control functions performed by controller 116 can be implemented in hardware, software, firmware, and the like, or a combination thereof. Controller 116 may communicate with chamber 104 (including any heating mechanism), print head 110, motor (not shown), and various sensors, calibration devices, display devices, and/or user input devices over suitable communication lines.

In some embodiments, controller 116 may also communicate with one or more of platen 106, platen gantry 108, head gantry 112, and any other suitable component of system 100. While illustrated as a single signal line, communication lines may include one or more electrical, optical, and/or wireless signal lines, allowing controller 116 to communicate with various components of system 100. Furthermore, while illustrated outside of system 100, controller 116 and communication lines can be internal components to system 100.

System 100 may also communicate with a computer 115 located with system 100 or remote therefrom, which may be one or more computer-based systems that communicate with system 100 and/or controller 116, and may be separate from system 100, or alternatively may be an internal component of system 100. Computer 115 includes computer-based hardware, such as data storage devices, processors, memory modules and the like for generating and storing tool path and related printing instructions. The computer 115 may transmit these instructions to system 100 (e.g., to controller 116) to perform printing operations.

During operation, controller 116 may direct print head 110 to selectively draw successive segments of the item and support material filaments from consumable assemblies 114. Print head 110 thermally melts the successive segments of the received filaments such that they become molten flowable materials. The molten flowable materials are then extruded and deposited from print head 110, along the printing z-axis axis, onto the receiving surface for printing the 3D item (from the item material), support structure (from the support material), and scaffold (from the item and/or support materials).

Print head 110 may initially print one or more layers of support structure onto receiving surface to provide a base for the subsequent printing. This maintains good adhesion between the layers of a 3D item and a build sheet, and reduces or eliminates any tolerance to flatness between the receiving surface of the platen 106 and the x-y plane.

After the support structure is initially printed, print head 110 may then print layers of the 3D item and scaffold, and optionally any additional layers of support structure. The layers of support structure are intended to support the bottom surfaces of the 3D item along the printing z-axis against curl forces, and any support layers are intended to brace the 3D item against gravity along the vertical x-axis. Printing is performed in this embodiment in a Z-direction indicated by arrow 120. X-Y-Z orientation indications are provided in FIGS. 1-4.

As layers of the item are printed in the horizontal direction, the print head 110 moves along print roads to build the item. In some embodiments, the print head 110 has enough variability in position to allow for the printing of a number of layers (in one embodiment on the order of one hundred (100) layers) before movement of the item is performed. Printing multiple layers without moving the item in one embodiment is performed because as the item is built, the weight of the item increases with each layer of the item built. On a system such as system 100, in which the length/size of the item is undetermined and can be quite large, an item can weigh several hundred pounds or more. Indexing to an item of such size and weight is difficult since moving an item of such size and weight is not as precise as the resolution to which the item is being printed. Accuracy of movement of, for example, a print head such as print head 110, is much higher. Therefore, accuracy of position of a smaller component can be much higher than accuracy in positioning the larger item.

To ensure sufficient position accuracy, a location sensing probe 118 is used in one embodiment to assist in registration for the printing of layers of an item being printed. Location sensing probe 118 is in one embodiment a plunger that is used to accurately determine a current Z-position so that a printing tip of a print head may be positioned to within a resolution on the order of one tenth the resolution of the print head. For example, with a printing resolution of on the order of 0.001-0.003 inches, the plunger 118 determines a current Z-position of the item being printed to 0.0001 inches, approximately ten times finer than the resolution of the print head. As print operations are typically performed within a heated chamber, thermal expansion of components such as the location sensing probe 118 can be significant. With temperatures in the chamber 104 running on the order of ˜350° F. (˜180° C.), thermal expansion on a component such as location sensing probe 118 could easily be on the order of 0.001 inches or more, rendering the resolution of the location sensing probe moot compared to the print resolution. In one embodiment, the location sensing probe components, especially the components that comprise the plunger portion of the location sensing probe, are specialized materials with low coefficients of thermal expansion, such as Invar®, a nickel-iron alloy. Further, as is described in further detail below, the temperature of the location sensing probe is on one embodiment maintained at or below about 212° F. (100° C.).

Movement of a large and/or heavy item is accomplished on one embodiment with a plurality of rails and drivers, such as are shown and described in further detail in FIGS. 2-8. Referring now to FIGS. 2-8, the gantry 108 is described in greater detail. With items that are printed horizontally, such as with a system 100 as described herein, a gantry such as gantry 108 is used to assist in supporting the item as it is printed and moved to allow further printing by the print head 110. Components of the gantry 108 and platen 106 assist in moving the item when it is desired to move the item.

As a horizontally oriented item may be much longer than the chamber or machine which is printing it, the item is eventually moved beyond the heated chamber. In a horizontally printed item, embodiments of the present disclosure move the item on the gantry 108 in a direction perpendicular to the printing plane. The platen 106 may be removed and set aside when a part, such as elongated part 2902 shown in FIGS. 29-30 is being printed with system 2900, to a length extending beyond the extent of the gantry 108. In one embodiment, after removal of the platen 106, the part 2902 is supported by a platform or table 2904 that is at the same height as the gantry 108 but allows extension of the elongated part 2902 beyond the gantry 108. The platform or table 2904 may be used to provide support for a part 2902 having a length greater than the gantry 108. The size of the table or platform 2904 may be selected depending upon the length to which the part 2902 is to be printed. It should also be understood that additional tables or platforms 2904 may be used to extend the support for the elongated part 2902 even further, without departing from the scope of the disclosure. FIG. 30 shows a system 2900 wherein a support table 2904 is used to support elongated part 2902 that extends past the gantry 108. In this embodiment, platen 106 is removed and set aside, in one embodiment on a separate table 2906.

FIG. 31 is a close-up view of the system 2900 with the platen 106 in a position in which it nears the end of the gantry 108. In this embodiment, as the platen 106 to which the three-dimensional item 2902 is secured approaches the end of the gantry 108, a limit switch system 3000 is engaged to stop further advancement of the platen 106 on the gantry 108. Limit switch system 3000 in one embodiment comprises a block 3002 secured to the platen 106, such as on a cross brace 3010 of the platen 106. Block 3002 carries or is attached to a contact arm 3004 that extends in one embodiment in an axis parallel to a direction of movement of the platen 106 on the gantry 108 away from the print head, as indicated by arrow 120. As the platen 106 approaches the end of the gantry 108, the contact arm contacts limit switch 3006, and the limit switch system 3000 instructs a controller or computer (such as controller 116 or computer 115) to stop motion of the platen. Limit switch system 3000 is shown as using a mechanical limit switch 3006. It should be understood that different types of switches, for example electrical switches, electromagnetic switches, and the like, could be used with limit switch system 3000 without departing from the scope of the disclosure.

Once limit switch system 3000 halts motion of the platen 106 as it nears the end of the gantry 108, the three-dimensional item, which is releasably secured to the platen 106, is released from the platen 106, the platen 106 is pulled away from the three-dimensional item, and removed. In one embodiment, the platen 106 is removed to a separate table such as table 2906 as shown in FIG. 24. Then, a support table, such as table 2904, is placed at the end of the gantry 108, and printing of the three-dimensional item continues without the platen 106. In this embodiment, the starter piece or pieces (e.g., 900 and/or 1200), that provide a base for the building of the three-dimensional item as described herein with respect to FIGS. 9-13, support the three-dimensional item. In one embodiment, the print foundation is releasably secured to the three-dimensional item, and the starter piece or pieces support the three-dimensional item when the print foundation is released from the three-dimensional item. Releasing the three-dimensional item from the print foundation (e.g., platen 106) is done in one embodiment when the three-dimensional item is indexed to near an end of the gantry 108.

While a platen 106 has been described herein in which a build sheet is fixed on the platen 106 or other component having a receiving surface, which may be a build sheet fixed on the platen 106 and held there with a vacuum, it should be understood that other releasably securable mechanisms for holding the three-dimensional item to the platen are amenable with the embodiments of the removable platen as described herein. By way of example only and not by limitation, such mechanisms include mechanical attachments (e.g., clamps, cams, or the like), magnetic attachments, electro-magnetic attachments, and the like.

As print resolutions become increasingly fine, a number of layers may be printed on an item before it is moved on the gantry 108. In 3D printing, there is a significant amount of movement of a print head along roads, and between roads. With the amount of movement of the print head in a printing operation, speed of movement of the print head, and also the printed item, becomes a factor. The speed and accuracy with which a smaller, lighter print head may be moved is higher than the speed and accuracy of movement of a large and heavy item. Moving a lighter weight component such as the print head is faster than moving a heavier item, which is a consideration in any manufacturing process. In embodiments of the present disclosure, multiple layers of an item are printed before any movement of the item. In one embodiment, the number of layers printed before moving the item is one hundred (100). All moves within the about one hundred (100) layers between movement of the item are performed by movement of the print head. Once about one hundred (100) layers have been printed, the item is moved. Although about one hundred (100) layers is discussed between movement of the item, it should be understood that a larger or smaller number of layers may be printed before movement of the item, and that the number of layers between item movements may be variable and depend on any number of factors including manufacturing conditions, print materials, the geometry of the item itself, and the like.

For example, in one embodiment, the horizontally printed item is moved on the gantry along a series of rails, using clamps and cylinders to adjust its position before the printing of additional layers of the item. FIG. 2 illustrates generally a configuration of system 100 including platen 106 and gantry 108. Platen 106 is movable along the gantry 108 in the direction of the Z-axis. Movement of the platen 106 along gantry 108 is performed in one embodiment as shown in FIGS. 3-8.

FIG. 3 is a top view of the system 100, showing platen 106, gantry 108, a torque tube 302, torque tube cylinder 304, and a series of driven rails 306, fixed rails 308, cylinders 304, 310, and clamps 305, 312, that work together in one embodiment to move an item being printed with system 100 along gantry 108. The clamps 305, 312 are in one embodiment linear pneumatic clamps that are positioned within the rails such that the clamps may releasably engage a three-dimensional item being printed with the system 100. Torque tube 302 is a tube or rod that is rotatably connected to the frame of the gantry 108, in one embodiment to edge rails 311 of the gantry 108, so as to be rotatable along an axis perpendicular to the edge rails 311. Torque tube cylinder 304 is connected to torque tube 302 to drive the torque tube 302 rotatably toward the cylinder 304 and rotatably away from the cylinder 304, when the cylinder 304 extends and retracts, respectively. The cylinder 304 is secured to the torque tube 302 with a mounting bracket or a pin. Torque tube is therefore rotatable between a first position in which it is rotated away from torque cylinder 304 and a second position in which it is rotated toward the torque cylinder 304, along a rotation indication arrow 322 (FIG. 6).

Driven rails 306 are connected to the torque tube 302. Four driven rails 306 are shown, although it should be understood that more or fewer driven rails 306 may be used without departing from the scope of the disclosure. Each driven rail 306 has a respective mounting bracket and clamp 312, and each clamp 312 is operable to secure a driven rail 306 to the item being printed on the platen 106 to fix the item with respect to the platen 106 and gantry 108, in one embodiment by inflation of a bladder with air cylinder 310 that engages the clamp 312 along a length of the driven rail 306. When a clamp 312 is secured to an item being printed, the item being printed is also secured against relative movement with the platen 106. The clamps in one embodiment are linear pneumatic clamps the extend along a length of an opening in their respective rail.

When it is desired to clamp an item being printed to the platen 106 with a driven rail 306, its air cylinder 310 engages the clamp 312. When the clamp 312 is engaged, the driven rail 306 and the item its clamp engages is fixed against motion relative to the platen 106. Rotation of the torque tube 302 toward the torque tube cylinder 304 when the driven rails 306 are clamped to the item being printed, which is fixed to the build sheet of platen 106 on which it is being printed, moves the driven rails 306 and therefore the platen 106 and its associated item toward the cylinder 304. Rotation of the torque tube 302 away from the torque tube cylinder 304 when the driven rails 306 are clamped to item being printed moves the driven rails and therefore the platen 106 and its associated item away from the cylinder 304. In one embodiment, the torque tube cylinder 304 extends and retracts approximately an inch, allowing for incremental motion of the driven rails 306, item being printed, and platen 106 by approximately the same amount when the driven rails 306 are clamped to the item being printed.

It should be understood that incrementing the platen 106 on the gantry may be in increments of greater than an inch by the use of a different torque tube cylinder length. In one embodiment, the coarse adjustment of the item is on the order of less than one inch to six inches. Further, the distance of the coarse adjustment does not need to be constant for each incrementing move of the platen. That is, depending upon part geometry and build parameters, the increment of motion of the platen 106 may be made at any distance within the range of available motion of the torque tube cylinder 304.

Indexing the part along with the platen 106, or after the platen 106 has been removed, may also be done according to the size of a thermal zone in the build chamber of the system 100, 2400. The increment of motion of the platen 106, or the three-dimensional item after removal from the platen 106, is chosen in one embodiment based on a size of the thermal zone within the build chamber that maintains a temperature of the three-dimensional item within a desired temperature range. That is, a print head (such as print head 110) may build up layers of a three-dimensional item within the desired thermal zone within the build chamber to maintain three-dimensional item temperature within a desired range. Once the print head is outside of the desired thermal zone, the part may be indexed along the gantry 108 or support table 2904 to maintain the printing operation within the desired thermal zone.

While printing in layers has been discussed, it should be understood that printing of a three-dimensional item may be along a non-planar tool path, such as a spiral or the like.

Fixed rails 308 are not connected to the torque tube 302, and therefore do not move as the torque tube 302 is rotated. Each fixed rail 308 also has a mounting bracket and clamp 312 for securing the clamp, and therefore the rail 308, to the item being printed in the same manner as described above with respect to the fixed rails 306. Fixed rail 308 clamps 312 are engaged during an item building operation. A center fixed rail, 308 c, serves in one embodiment as an alignment rail. The alignment rail is used in one embodiment to align an item on the platen 106 and gantry 108, as is discussed in greater detail below.

Sequential clamping of clamps 312 and movement of the driven rails 306 allows the movement of an item along the gantry 108 as follows. During an item building operation, that is, when layers are being printed to the item, all clamps 312 of rails 306 and 308 are clamped against motion of the item being printed and therefore the platen 106 relative to gantry 108. To move the platen 106 and therefore an item away from the print head along the gantry, that is, toward an end 320 of the gantry 108 distal to the print head and initial position of platen 106, the clamps 312 of the fixed rails 308 are released. The driven rails 306 remain clamped. The torque tube cylinder 304 is retracted so that the driven rails 306, the platen 106, and the item being built move toward the torque tube cylinder 304 and the second position. In this manner, the item is moved toward the distal end 320 of the gantry 108. When the movement is complete, the clamps of the fixed rails 308 are clamped, and the clamps of the driven rails 306 are released. The torque tube cylinder 304 rotates the torque tube 302 away from the cylinder 304 to the first position, moving the driven rails 306 back to their first positions while the platen 106 and therefore the item being printed do not move. All clamps of rails 306, 308 are again clamped for a build operation, and the process repeats as necessary for moving the item on the gantry 108. The process allows for movement of the platen 106 and the item being built along the gantry to whatever position is desired.

In one embodiment, each clamp 312 comprises a pneumatic clamp that is engaged when a silicon bladder positioned within a slot of its rail is inflated by its respective air cylinder 310. Alternatively, each mounting bracket could be engaged when its silicon bladder is deflated. Further, it should be understood that although pneumatic clamps are disclosed, other clamps or mounting brackets suitable for engaging and disengaging the rails 306 and 308 are suitable for use with the various embodiments, such as electric clamps, mechanical clamps, and combinations thereof, and are within the scope of the disclosure and of one skilled in the art.

In one embodiment, each of the rails other than the center rail 308 c has two movable edge portions, so that the rails float in the X direction. Center rail 308 c comprises one fixed edge portion, and one movable edge portion. Therefore, the position of the fixed edge portion of center rail 308 c is known and unchanging, so that the center rail 308 c is fixed in the X direction.

FIGS. 4-5 show closer views of the portion of the gantry 108 where the rails 306 and 308 interact with the torque tube 302 and torque cylinder 304.

FIG. 6 is a perspective view of the torque tube 302, torque tube cylinder 304, and rails 306 and 308 of the gantry 108 without other components shown, to more clearly show their arrangement. The torque tube is rotatable as shown by arrow 322 to allow for the movement of the driven rails 306 forward and back between their first and second positions with the extension and/or retraction of the torque tube cylinder 304.

FIGS. 7 and 8 are perspective views of the platen 106 and center fixed rail 308 c (FIG. 7) and the platen 106 on gantry 108 (FIG. 8). As is seen in FIGS. 7-8, a guide portion 702 of platen 106 is connected to a T-shaped member 704. T-shaped member 704 has a substantially vertical portion that moves within slot 706 of center fixed rail 308 c, which is used in this embodiment as an alignment rail. An item being printed is guided along the gantry 108 through the interaction between the T-shaped member 704, the guide slot 706, and the clamps 312 of the gantry 108. T-shaped member 704 functions in one embodiment as a center alignment keel, and in one embodiment, it extends from a front portion of the guide portion toward the front part of the platen 106, near to where a starter piece (such as starter pieces 900 and 1200 described further below) is used. The center alignment keel allows for centering of the platen 106 on the gantry 108. Travel limit sensors 710 are used in one embodiment to limit the movement of the platen 106 so that it does not travel outside of defined position limits. Platen 106 further has support pads 714 at its front and its rear, which serve to support the platen 106 on the gantry 108 (shown and described in further detail with respect to FIGS. 14-16 below). When a clamp 312 for a rail 306 or 308 engages, the keel for that particular rail is clamped to its rail so that it cannot move except with movement of the rail. Therefore, in the motion of the driven and non-driven rails is made, the movement of the clamped rails also moves the platen 106, and consequently, an item that is being printed.

In building very long parts or parts in segments, new layer alignment in the X-Y plane may become problematic. Small misalignments can lead to larger overall errors as part length increases. Alignment of a new layer to a previously printed layer is performed in smaller systems with a continuous Z motion mechanism that provides proper tolerances. Once a part gets larger, continuous Z motion mechanisms that are longer than the entire part are difficult to build, and can become unwieldy. In one embodiment, at the boundary of the Z axis, a separate mechanism is used to move the part to allow the Z axis to recover its length and to continue building the part. These functions are discussed herein as local Z and the Z drive respectively. The Z drive operates in various embodiments as described herein. The Z drive allows for movement of a part in a Z direction. Once a part has been shifted in the Z direction by the Z drive, alignment in the X-Y plane may not be accurate. In order to continue properly aligned part building, registration in the Z direction is performed, such as by using the location sensing probe as discussed herein, and registration in the X-Y plane is performed as follows. Once the Z registration is performed, the part location in Z is known. To register the part correctly in the X-Y plane, in one embodiment, an X-Y fiducial is used. As the part moves back in Z, particularly at the index position, the part can shift in X and Y. To manage that shift, the X-Y fiducial is built into the part and is measured using a location sensing probe (e.g., a contact probe or a non-contact measurement system as described herein). The use of such a measurement of the fiducial allows the system 100 to adjust an X-Y offset of the part each time the offset is measured.

Such a fiducial may be part-based, that is, on the part being printed, or may alternatively be in a support structure. While the fiducial may be formed from support material or from part material, when the fiducial is formed from part material, the fiducial behaves in the same way that the part does during cooling, such as but not limited to the amount and timing of sag, and the like. That is, when the fiducial is formed out of the same material as the part, the fiducial behaves similarly to the part in the build chamber (e.g., if the part sags, the fiducial also sags.

Use of a fiducial, either part-based or support-based, provides a method for determining the XY alignment and the Z displacement. In one embodiment, a fiducial comprises a specific part geometry that is constructed along with the target geometry. A measurement system capable of measuring the embedded fiducial geometry determines X-Y alignment. In one embodiment, the part geometry of the fiducial comprises a right angle of material constructed at a known location relative to the target geometry. One or more fiducials may be constructed on each layer of the part.

A single fiducial on a part is shown in FIG. 22. FIG. 22 shows a part 2202 with a single fiducial 2204. The fiducial 2204 is constructed in a manner that allows a measurement system (such as the location sensing probe 118) to properly determine the location of the fiducial in X and Y. Fiducial 2204 is shown in closer detail in FIG. 23. Fiducial 2204 comprises in this embodiment a known X-Y offset point 2206, an X reference edge 2208 extending from the known offset point 2206, and a Y reference edge 2210 extending orthogonal to the X reference edge from the known offset point 2206. The known offset point 2206 is the vertex of a right angle having sides 2208 and 2210. As shown, the fiducial 2204 is on a part 2202. However, when the part being printed uses support structures, a fiducial or fiducials may alternatively be built into the support structure without departing from the scope of the disclosure.

Just prior to displacing the part in Z with the Z drive, the system in one embodiment measures the Z location, such as with the location sensing probe described herein, and measures a location of the fiducial to get a known X-Y location before movement of the part. Once the part is displaced, the Z location of the part and the X-Y location of the fiducial are determined again, providing a new location in X, Y, and Z. The new location of the fiducial is compared to the previous location of the fiducial, or to the planned part location. The new Z location is compared to the previous Z location. This information allows the system to compensate on the fly for the Z displacement as well as X-Y alignment. In another embodiment, use of more than one fiducial may be used to compensate for XY rotation, and for shifts in the Z plane.

In operation, a method for determining an X, Y, and Z position comprises determining a Z position as described herein, and determining an X and a Y position as follows. A measurement system determines the location of the Y reference edge 2210 by moving an element, such as a probe, to contact the Y reference edge 2210, giving the Y location. The measurement system determines the location of the X reference edge 2208 by moving the element to contact the X reference edge 2208, giving the X location. Once the X and Y locations of the reference edges 2208 and 2210 are known, the offset point 2206 is known, and a precise location in X-Y is also known. Coupled with the determined Z position, the position of the part in X, Y, and Z is known to the precision of the probe. In one embodiment, a measurement system used for determining X and Y positions uses on the order of 0.25 inches of clearance with X and Y reference edges of at least 0.02 inches long. As measurement elements continue to improve, clearance and length of reference edges may change without departing from the scope of the disclosure.

Embodiments of the present disclosure are capable of printing multiple layers of a part before movement of the part is effected by the system 100 as described herein. While X, Y, and Z position can be determined after each layer, in one embodiment, multiple payers are printed before X, Y, and Z positions are determined. In one embodiment, before the system 100 moves the part after a number of layers have been printed, the X, Y, and Z positions are determined as described herein. Following movement of the part in the Z direction, another determination of the X, Y, and Z positions is made for registration of subsequent layers on the part.

A fiducial, such as fiducial 2204, is generated in one embodiment using a digital file built with the fiducial appropriately configured in the digital file. Given part geometry, an element of the actual part may be suitable for use as a fiducial without any modification. This could occur, for example, where the part has a defined right angle edge that is properly aligned with the build platform. In this embodiment, the feature structure of the part may be used as a fiducial. In other embodiments, a fiducial is built into support structure for the part. Creating a fiducial comprises in one embodiment generating a digital file containing a fiducial, and building a part with the file. A file for building a part in this manner contains structure therein with a known substantially horizontal and a known substantially vertical component that is capable of being used as a fiducial.

A method 2400 of building a three-dimensional item in an additive manufacturing system is illustrated in flow chart form in FIG. 24. Method 2400 comprises printing a support structure for the three-dimensional item in a layer by layer manner along the printing axis in block 2402, and printing a layer of the three-dimensional item while supporting the three-dimensional item laterally relative to the printing plane with the support structure while printing the three-dimensional item in block 2404. Building the part further comprises printing a fiducial structure having a known substantially vertical and a known substantially horizontal component. Printing the three-dimensional item in a layer-by-layer manner is performed in one embodiment along a horizontal printing axis parallel to a build plane in the additive manufacturing system. Printing the fiducial structure comprises printing the fiducial structure in the support structure in one embodiment, or as a portion of the three-dimensional item in another embodiment.

Method 2400 may further comprise printing a plurality of layers of the three-dimensional item, including the fiducial structure in block 2406, determining a Z position of the three-dimensional item in block 2408, determining an X and Y position of the three-dimensional item using the fiducial structure in block 2410, moving the three-dimensional item along the horizontal printing axis in block 2412, determining a new Z position of the three-dimensional item in block 2414, determining new X and Y positions of the three-dimensional item using the fiducial structure in block 2416, and printing another plurality of layers of the three-dimensional item in block 2418. The printing of another plurality of layers uses the new positions of X, Y, and Z to register the another plurality of layers to the previously printed layers. In one embodiment, determining an X and a Y position for the three-dimensional item comprises moving the location sensing probe vertically to contact a known substantially horizontal edge of the fiducial to determine the X position, and moving the location sensing probe horizontally to contact a known substantially vertical edge of the fiducial to determine Y position.

In additive manufacturing systems, a byproduct of printing is waste material that can build up on a print head or tip, material extruded from a print head to expend one material to be replaced by another, material that has been stored for a period of time in a print head that has degraded, and the like. The process of additive manufacturing uses automated cleaning maintenance and priming of the modeling tool for quality printing and for accurate auto calibration of the modeling tool. For example. in additive manufacturing, multiple tools may be swapped in and out during the part build to alter materials, colors, and tool tips of varying geometries. As the tool tip location varies slightly due to tolerances the tip position is learned so its position can be aligned with the prior tool's tip location. Contamination or buildup on the modeling tip may compromise the accuracy of the homing calibration process. Further, prior to being swapped in, the modeling tool may have been stored for a period of time. The material resident in the tool is subject to degradation and may be purged and refreshed with new material in order to prevent part quality issues.

In one embodiment, a waste purge system removes purged waste material from the tool service location to a waste location. Conventional disposal processes are oriented vertically where gravity can be used for transport of the waste material. In embodiments of the present disclosure which use a vertical print plane and horizontal printing, a separate system is used to transport waste material horizontally. In one embodiment, a high volume vacuum is used to collect and transport material that is discharged from a modeling tool oriented horizontally. This method may also be utilized to enhance the efficiency and speed of a conventional vertical modeling tool.

As illustrated in FIGS. 25, 26, 27, and 28, the modeling tool traverses in a vertical XY plane to build a part that grows in the Z direction. The purged material is transported in the horizontal Z direction as well. FIG. 25 shows an isometric view of a vacuum purge system 2502 along with a modeling device 2501, and waste bin 2503. Purge system 2502 includes tip sensing apparatus 2504 and 2505, and tip cleaner 2506. Tip cleaner 2506 is used to scrub any residual material from the modeling tip before tip sensing apparatus 2504 and 2505 sense the tip location. A tip cleaner such as tip cleaner 2506 is disclosed in further detail in U.S. Pat. Nos. 6,722,872 and 7,744,364, which are commonly owned by the assignee of the present disclosure. Sensor 2505 is in one embodiment an open close contact that detects the tip location in the Z direction, and sensor 2504 is in one embodiment a camera to detect the tip location in the X Y directions. Sensor 2504 is surrounded in one embodiment by a light array 2507 to better illuminate the tip for the camera. FIG. 25 shows the model tool in a purge position, FIG. 26 shows the model tool in a Z detection position, and FIG. 27 shows the model tool in an XY measuring position. Items 2516 are structural members used to locate and support the purge components.

FIG. 28 shows a close-up perspective view of a portion of the purge system 2502 in greater detail. Purge system 2502 further comprises a vacuum generator 2508 (such as, for example only, a model ZH10-X185 available from SMC Corporation), a tube fitting 2509 to which a plastic tube 2510 is attached, and to which air of sufficient pressure and flow is provided to enable vacuum generator 2508 to produce a vacuum into tube 2512. Tube 2512 is, in one embodiment, a tube with suitable inside geometry to draw in without obstruction purged material from a modeler tool (such as tool 2501). Tube 2512 may use tapered geometry to allow a less precise location of the modeling tip. Alternatively, tube 2512 may be reduced in diameter to increase air velocity to better draw in the purge, or configured in other ways that will be apparent to those of skill in the art to benefit the purge process.

An unobstructed low friction straight tube 2513 directs the purge material to an external waste container 2503 (see FIGS. 25-27). Coupling 2514 couples tubes 2512 and 2513 and in one embodiment, has a small angle to redirect the purge material to the straight tube 2513, and deflector 2515 is also angled so as to direct the purged material into waste bin 2503 without creating an obstruction to block purge material. It should be understood that the angles of such tubes and couplings may be modified without departing from the scope of the disclosure.

Starter Pieces

Referring now to FIGS. 9-13, views of starter pieces (e.g., starter keels) 900 (FIGS. 9-11) and 1200 (FIGS. 12-13) are shown. The starter pieces fit under the platen 106 and above the rails of the gantry 108 to provide a base for the building of the item. FIG. 9 show starter piece 900 in perspective. Starter piece 900 is a center starter piece, and comprises a main body 910 comprising a face surface, a keel 902 coupled to the main body 910 and including keel body 904 and guide tab 906, and at least one retaining mechanism 908. Keel face surface 910 has a thickness 912. The thickness 912 is chosen in one embodiment to allow an abutting match of thickness between the main body 910 and a build sheet mounted to the platen 106, so that at a start of a build operation for an item, front edge 914 aligns with the build sheet to form a smooth transition therebetween. Keel body 904 has a width 916. This width allows the keel body to align with center guide rail (e.g., center rail 308 c) of gantry 108 to assist in alignment of the item on the gantry 108. The width 916 of keel body 904 allows the center starter piece 900 to be fixed with respect to x-axis movement.

Guide tab 906 fits into a slot (not shown) in center rail (e.g., center rail 308 c) to assist in fixing the starter piece 900 with respect to y-axis movement. The engagement of guide tab 906 with the slot in the rail helps the item to not float in the Y-direction.

Starter piece 1200 is a non-center starter piece, is shown in FIGS. 12-13, and comprises a main body 910 comprising a face surface, a keel 1202 coupled to the main body 910 and including keel body 1204 and guide tab 1206. At least one retaining mechanism 908, main body 910, and keel front edge 914 are identical to those parts of keel 900. Main body 910 of starter piece 1200 has a thickness 912 the same as main body 910 of keel 900. Keel body 1204 has a width 1216 which allows the keel body 1204 to align with guide rails 308 that are not a center guide rail (308 c) of gantry 108. The width 1216 of keel body 1204 allows the starter piece 1200 to float with respect to x-axis movement.

FIG. 14 shows a close-up perspective view of a portion of the platen 106, starter pieces 900 and 1200, and their interactions with the rails 306/308 of the gantry 108. Parts have been removed to show more clearly the positioning and interaction between the parts. Specifically, the area marked as area 1402 has had the platen face panel removed; the area marked as area 1404 has had the platen face panel, support structure for the platen panel, and a starter piece 1200 removed; the area marked as area 1406 has had the platen face panel, support structure for the platen panel, and a portion of the rail 308 c removed; and the area marked as area 1408 has had the platen face panel, support structure for the platen panel, a portion of the rail 306, and a starter piece 1200 removed. The various views allow the showing of the engagement of starter pieces such as keels 900 and 1200 with rails such as rails 306 and 308.

Keels 900 and 1200 as shown in areas 1406 and 1402, respectively, have protrusions 918 that comprise in one embodiment the at least one retaining mechanism 908. The protrusions 918 engage openings 1412 in the platen 106. Gaps 1412 are better seen without a starter piece in area 1404. The double protrusions 918 allow a starter piece to be snapped into the gap, and further, provide a protection against torque twisting of the starter pieces during item production. Because there are two independent protrusions 918, vibrations and torsions of the platen 106 and the starter piece mounting area are dampened, so that the movement is not imparted to the starter piece main bodies 910, to help maintain continuity in the build process, and improves the quality of items being built. Since the starter pieces 900 and 1200 do not bend with movement of the structure into which they are snapped, build quality is improved allowing for items to be built with increasingly tight tolerances. When items are manufactured with tight tolerances, any variation due to machine part vibration or the like can be imparted to the item. The double protrusions 918 assist in reducing such a transfer of vibration from the apparatus to the item.

In building an item on the starter pieces and the build sheet, the geometry of the starter pieces is extended during the build operation to provide a platform to support the item during the build operation. The starter piece geometry is extended for the length of the build, providing support for the item during the build operation.

Referring now to FIG. 15, a view similar to that of FIG. 14 is shown, but with the components of the apparatus 100 shown again. Platen 106 is shown with its positioning directly above starter pieces 900 and 1200. In one embodiment, one center starter piece 900 is used, and eight non-center starter pieces 1200 are used, with four starter pieces 1200 on each side of center starter piece 900. It should be understood that more or fewer starter pieces 1200 may be used without departing from the scope of the disclosure, and depending upon the size of the item to be built. Each starter piece is associated with one of a driven rail 306 or a fixed rail 308. Driven rails and fixed rails in one embodiment alternate in the x-direction on the gantry 108. Center starter piece 900 is placed at center rail 308 c in one embodiment. In one embodiment, support rails 1410 are placed between driven rails and fixed rails so that no more than about 12 inches separates consecutive support rails 1410. As can be seen, support rails 1410 alternate with driven and stationary rails 306 and 308, so that there is y-direction support for a built item on the order of every six inches horizontally.

Referring now to FIG. 16, a close-up view of a portion of FIG. 15 is shown. FIG. 16 shows center starter piece 900 in place on center rail 308 c, including keel 902 engaging slot 706 of center rail 308 c, and guide tab 906 engaging horizontal slot 1602 in slot 706. Similarly, each starter piece 1200 has its keel 1206 engaging slot 708 of its respective driven or stationary rail 306 or 308, and its guide tab 1206 engaging horizontal guide tab slot 1604 in slot 708. Support pads 714 of platen 106 rest on support rails 1410. It is on these support rails 1410, under support pads 714, that the platen 106 slides during movement of the platen on the gantry. The support pads convey the weight of the platen 106 and item to the support rails 1410, and then to the ground.

The support rails 1410 sit at a location below a bottom of the item being printed. The starter pieces 900 and 1200 are used as a base from which to print down to form supports for the item being printed that extend to the support rails. As the platen 106 moves on the gantry 108, the item being printed transfers some of its weight to the platen, and some of the weight caused by the moment as the item extends away from the platen 106, to the support rails 1410 through the extended support formed from the starter pieces. Further, the geometry of each starter piece is replicated in the z-direction as well, to allow the platen 106 to be secured with mounting brackets 312 by their engagement with the extended geometry of the starter pieces within the slots of the rails 306 and 308 as the item is printed.

The keels 902 and 1202, and guide tabs 906, 1206, of starter pieces 900, 1200 engage slots in rails 306, 308 of the gantry. The keels 902, 1202 restrain movement of the starter pieces in an x-direction (as the x-direction is shown in the FIGS.) Specifically, keel 902 is nearly as wide as the width of its associated slot in center rail 308 c, and serves as an alignment keel to restrict movement of the starter piece, and therefore of the platen and item being printed, in the x-direction. The keels 1202 of starter pieces 1200 are narrower than their associated slots in driven or fixed rails 306, 308, and float in the x-direction to allow the wider keel 902 in the center rail 308 c to be the alignment keel for the platen 106 and the item being printed. Horizontally extending guide tabs 906 and 1206 engage horizontal channels extending from the slots in their respective rails, and restrict motion of the starter pieces, and therefore the platen and item being printed, in a y-direction (as the y-direction is shown in the FIGS.) Referring also to FIG. 16, the guide tab 906 engages channel 1602 in slot 706 of guide rail 308 c, and guide tabs 1206 engage channels 1604 in slots 708 of remaining rails 306, 308, to prevent the starter pieces 900, 1200, the platen 106, and the printed item from moving in the y-direction.

In printing an item using embodiments of the system described herein, the print head initially prints multiple layers of a support structure on a starter piece during printing of the item itself, the support structure being printed layer-by-layer as described herein. The layers of the support structure are in one embodiment printed with increasing cross-sectional area in the vertical x-y plane to extend, at an angle of approximately 45 degrees in one embodiment, toward the support rails 1410 to ultimately provide support for the item by the support rails 1410 and not the starter pieces 900, 1200 or platen 106. This layering build-up is in one embodiment continued until the footprint cross-sectional area of the intended 3D item and support to the support rails 1410 is reached. At that point, the support rails 1410 support the weight of the item, relieving pressure on the item itself and the starter pieces 900, 1200. The geometry of the starter pieces 900, 1200 is printed and maintained along the length of the item in one embodiment, to allow for continued control of movement of the platen 106 and therefore the item with respect to the gantry 108.

In one embodiment, after approximately 100 layers of support structure and an item are printed, the item and its support structure are moved as described herein. As the item is moved as described herein, the item and its associated structure is moved in the direction of arrow 120 (FIG. 1), and the support structure slidably engages the support rails 1410, which support the weight of the item through the support structure formed extending from the starter pieces. This allows the support structure to rest on and slide across the top surface of support rails 1410 while platen 106 is indexed in the direction of arrow 120.

Removal of the item from the printed support and starter pieces after the piece is completed may be performed in various ways as is known in the art. The printing and indexing apparatus and methods described herein are amenable to use with various removal methods and structures.

Location Sensing Probe

A location sensing probe 118 such as that discussed above is shown in greater detail in FIGS. 17-21. Location sensing probe 118 in one embodiment acts as a probe to determine a location of a printed item or component of the system 100 described herein. FIGS. 17-19 show the location sensing probe 118 having a body 119. Location sensing probe 118 is shown with its outer tube 1702 intact (FIG. 17), its outer tube 1702 removed to reveal inner tube 1802 (FIG. 18), and its inner tube 1802 removed to reveal rod 1904 of plunger 1701 (FIG. 19). Location sensing probe 118 comprises in one embodiment plunger 1701, tool change plate 1706, tool change mount 1708, circuitry 1710, crash stop 1712, and control module 1714. Plunger 1701 includes outer tube 1702 and probe end 1704 with location sensing probe components such as, for example, contact sensor location sensing probes manufactured by Keyence Corporation as shown in FIG. 17, inner tube 1802 with stop hole 1804 and air flow ports 1806 as shown in FIG. 18, and stop bar 1904 passing through opening 1903 of probe bar 1902 to limit travel of probe bar 1902 as shown in FIG. 19.

Outer tube 1702 in one embodiment includes air flow openings 1716 disposed near the connection of outer tube 1702 to the main body 119 of location sensing probe 118. Air flow openings 1716 cooperate with air flow ports 1806 (FIG. 18) to circulate cooling air within the plunger 1701 to maintain its temperature as described above. Tool change plate 1706 is in one embodiment a quick change plate such as, for example, a QC-28 tool change plate manufactured by ATI Industrial Automation located in Apex, N.C. Other tool change plates may be used without departing from the scope of the disclosure. Tool change plate 1706 also includes pneumatic connectors 1707 for connection of pneumatic hoses used in probe operation. Tool change mount 1708 is in one embodiment a quick change tool changer such as, for example, a QC-11 tool changer also manufactured by ATI Industrial Automation. Other tool change mounts may be used without departing from the scope of the disclosure. Circuitry 1710 includes a printed circuit board containing circuitry for operation of the location sensing probe 118, and connection to electronic components of the location sensing probe 118. Crash stop 1712 is a Z-axis crash stop that limits Z-axis motion so that the crash stop 1712 stops motion of the probe tip instead of the probe tip being subjected to force at a hard stop. Control module 1714 connects to circuitry 1710 and to other components to assist with location sensing probe operation.

FIG. 18 shows the location sensing probe 118 with outer tube 1702 removed to reveal another layer of plunger 1701. Inner tube 1802 houses probe bar 1902 (FIG. 19) and other location sensing probe components, and has stop openings 1804 (one shown) and air flow ports 1806.

FIG. 19 shows the location sensing probe 118 with the outer tube 1702 and inner tube 1802 removed to reveal another layer of plunger 1701. Probe bar 1902 has an opening 1903 through which stop bar 1904 is placed. Ends 1905 of stop bar 1904 extend into stop openings 1804 to provide a hard stop position for the motion of probe end bar 1902. Air port 1906 is shown in face plate 1908 of the location sensing probe body. In one embodiment, cooling air is passed into to space between probe bar 1902 and inner tube 1802 to maintain the internal portions of the plunger 1701 at or below the desired temperature as described above. Heated air is exhausted from inner tube 1802 through air flow ports 1806 into the annular gap between inner tube 1802 and outer tube 1702, and is exhausted therefrom through ports 1716. Cooled air is supplied to port 1906 in one embodiment through air port 1711 (FIG. 20) shown and described in greater detail below.

FIG. 20 is a rear perspective view of the location sensing probe 118, and shows in greater detail conical opening pneumatic ports 1709 that pass through tool change plate 1706 to pneumatic ports 1707. The pneumatic ports connect via pneumatic connectors, hoses, or the like to ports for the plunger 1701 for pneumatic operation thereof. Air port 1711 is provided in tool change plate 1706 to direct cooling air to port 1906 (FIG. 19) to control a temperature for the components of plunger 1701 which limits thermal expansion thereof in a heated work environment, as described above. FIG. 20 also shows an electronics connector 2002 for the tool changer. The electronics connector is coupled to the circuitry 1710 and the control module 1714 of the location sensing probe 118. Electrical connectors 2004 connect to external electronics to pass electrical information across the tool change interface.

Referring to FIG. 21, another perspective view of location sensing probe 118 is shown, rotated approximately 180 degrees from the view of FIG. 20 to show further electrical conduit connector 2006, and connector conduits 1715 of control module 1714.

In operation, the location sensing probe 118 is used to register the location of the platen at an initial item build, and is used to register the location in the z-axis of the item being built as it is being built, or any portion of the item as it is being built. With the resolution of the location sensing probe 118 being smaller than the resolution of the print head printing, the location of the item, platen, build sheet, or the like is determined by the location sensing probe 118 with an accuracy that is more fine than the resolution of the print head. Registration operation in one embodiment includes moving the location sensing probe 118 so that probe end 1704 comes into contact with the platen or part to be indexed in the Z-direction. Once the probe end contacts the platen or part, a rough Z-position is known. The location sensing probe backs away from the platen or part, and at a slower speed, and knowing the rough location of the platen or part, refines the Z-position by once again moving into contact with the part or platen. This coarse-fine indexing allows for a more accurate Z-position determination.

In another embodiment, X-Y indexing of the system is also performed with the location sensing probe 118. Each location sensing probe 118 has its own configuration of the tip end (e.g., tip end 1704). An imaging device, such as a camera, is used to capture an image of the tip end along a longitudinal axis of the location sensing probe 118. The tip center is located in the image, and the X-Y positioning of the location sensing probe is enhanced. For each new tool that is loaded with the tool changer, a new image of the tip end is taken, as tips have different centers and configurations.

In one embodiment, the plunger portion 1701 of location sensing probe 118 that extends into a heated chamber (such as chamber 104) is constructed at least in part from a material or materials that have a low coefficient of thermal expansion, to further control to a temperature for the components of plunger 1701 which further limits thermal expansion thereof in a heated work environment, as described above. In one embodiment, a low coefficient of thermal expansion material includes ceramic.

In another embodiment, in-situ part location determination using a fiducial may be performed using an element that does not make direct contact with a part. By way of example only, and not by way of limitation, ultrasonic, optical, and laser based measurement systems may be used to determine in-situ part location, without departing from the scope of the disclosure.

An embodiment of a non-contact fiducial measurement device (e.g., ultrasonic-, optical-, or laser-based) for in-situ part position measurement includes a sensor that can image or otherwise recognize a fiducial feature such as feature 2204 shown in FIG. 22. With the same or a similar fiducial feature in the constructed geometry of the part or support structure, an embodiment of a non-contact distance-based measurement system determines the part location as follows.

A sensor of the measurement system is placed above the horizontal fiducial feature by an amount greater than a possible part position error. The sensor is then moved down while incrementally taking distance measurements to the fiducial. These vertical measurements allow the production of a distance map of the part fiducial. Using the distance map, a center of the horizontal portion of the fiducial is located. The sensor is then positioned to the side of the vertical portion of the fiducial, and is moved over the fiducial in the same manner as the vertical scan, performing horizontal measurements of distances to the fiducial feature at the incremental distances. The horizontal distance measurements allow the production of a distance map for the part fiducial in the horizontal direction. Using the distance map, a center of the vertical portion of the fiducial is located. Using the determined horizontal and vertical fiducial center point positions, the current part location may be determined within the current build coordinate system. It should be noted that while horizontal and vertical coordinates are discussed herein, it should be noted that the determination of a center position of a fiducial may be performed with a different coordinate system without departing from the scope of the disclosure.

Although the present disclosure has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the disclosure. 

1. A location sensing probe for an additive manufacturing system, comprising: a probe body having a first air port therethrough between an inlet and an outlet; and a plunger extending from the probe body, the plunger comprising: a probe end; and a probe bar, the probe bar coupled between the probe body and the probe end; and a channel surrounding the probe bar, the channel comprising an inner tube having an inlet proximate the probe body and an outlet proximate the probe end.
 2. The location sensing probe of claim 1, wherein the plunger further comprises an outer tube, the outer tube surrounding the inner tube between the probe body and the probe end, the outer tube having an outlet at an end thereof proximate the probe body.
 3. The location sensing probe of claim 1, wherein the probe body comprises; a tool change mount; a tool change plate having a second air port therethrough connectable between a cooling air supply and the probe body air port inlet; and a printed circuit board and a control module for control and operation of the probe.
 4. The location sensing probe of claim 1, and further comprising a crash stop extending from the probe body.
 5. The location sensing probe of claim 1, wherein the location sensing probe is configured to determine a position of the item being printed relative to a print head.
 6. The location sensing probe of claim 5, wherein determining a position comprises probing the position with a plunger having a resolution finer than a print resolution of the print head.
 7. The location sensing probe of claim 1, wherein the channel is configured to supply cooling air flow to the plunger to limit thermal expansion thereof.
 8. A method of building a three-dimensional item in an additive manufacturing system, comprising: printing a support structure for the three-dimensional item in a layer by layer manner along the printing axis; and printing a layer of the three-dimensional item while supporting the three-dimensional item laterally relative to the printing plane with the support structure while printing the three-dimensional item; and wherein building the part further comprises printing a fiducial structure having a known substantially vertical and a known substantially horizontal component.
 9. The method of claim 8, wherein printing the three-dimensional item in a layer-by-layer manner is performed along a horizontal printing axis substantially perpendicular to a build plane in the additive manufacturing system.
 10. The method of claim 8, wherein printing the fiducial structure comprises printing the fiducial structure separate from the three-dimensional item.
 11. The method of claim 8, and further comprising printing a support structure for the three-dimensional item in a layer by layer manner along the printing axis.
 12. The method of claim 11, wherein printing the fiducial structure comprises printing the fiducial structure in the support structure.
 13. The method of claim 8, wherein printing the fiducial structure comprises printing the fiducial structure as a portion of the three-dimensional item.
 14. The method of claim 8, and further comprising: printing a plurality of layers of the three-dimensional item, including the fiducial structure; determining a Z position of the three-dimensional item; determining an X and Y position of the three-dimensional item using the fiducial structure; moving the three-dimensional item along the horizontal printing axis; determining a new Z position of the three-dimensional item; determining new X and Y positions of the three-dimensional item using the fiducial structure; and printing another plurality of layers of the three-dimensional item.
 15. The method of claim 8, and further comprising: probing the fiducial to determine system coordinates; comparing the determined system coordinates to build coordinates for the three-dimensional item; calculating a shift amount when a discrepancy exists between the determined system coordinates and the build coordinates; and shifting the print head by the shift amount when a discrepancy exists.
 16. The method of claim 14, wherein determining an X and a Y position for the three-dimensional item comprises moving a location sensing probe vertically to contact a known substantially horizontal edge of the fiducial to determine the X position, and moving the location sensing probe horizontally to contact a known substantially vertical edge of the fiducial to determine Y position.
 17. The method of claim 14, wherein determining an X and a Y position for the three-dimensional item comprises determining with a non-contact location sensing probe.
 18. The method of claim 17, wherein determining with a non-contact location sensing probe comprises: sensing incremental distance measurements between the fiducial and the sensor in a substantially vertical direction; determining a distance map of the fiducial in the substantially vertical direction; sensing incremental distance measurements between the fiducial and the sensor in a substantially horizontal direction; determining a distance map of the fiducial in the substantially horizontal direction; determining a center point of the fiducial in the substantially vertical and substantially horizontal directions; and determining a current part location within the current build coordinate system from the determined center point of the fiducial.
 19. A method of determining a position of an item being printed in an additive manufacturing system, comprising determining the position with a location sensing probe having a resolution finer than a print resolution of the print head.
 20. The method of claim 19, wherein determining a position of the item is done with respect to a position of a print head.
 21. The method of claim 19, and further comprising: printing a support structure for the item in a layer by layer manner along the printing axis; and printing a layer of the item while supporting the item laterally relative to the printing plane with the support structure while printing the item.
 22. The method of claim 21, wherein the item and the support structure are printed onto the print foundation retained by the additive manufacturing system, and wherein the method further comprises indexing the print foundation along the printing axis.
 23. The method of claim 21, and further comprising removing the support structure from the item after completing the printing of the three-dimensional item.
 24. The method of claim 19, and further comprising compensating for ambient temperature in the probe.
 25. The method of claim 24, wherein compensating for ambient temperature in the probe further comprises cooling a location sensing probe of the probe.
 26. The method of claim 25, wherein cooling a location sensing probe of the probe comprises passing a cooled gas through a channel formed between air ports of the location sensing probe surrounding a probe bar and probe end.
 27. The method of claim 20, wherein determining the position comprises determining a Z position for the item, and determining an X-Y position for the item.
 28. The method of claim 27, wherein determining an X-Y position for the item comprises moving the location sensing probe vertically to contact a known substantially horizontal edge to determine the X position, and moving the location sensing probe horizontally to contact a known substantially vertical edge to determine Y position. 